Abstract
During the intracellular life of Salmonella enterica, a unique membrane-bound compartment termed Salmonella-containing vacuole, or SCV, is formed. By means of translocated effector proteins, intracellular Salmonella also induce the formation of extensive, highly dynamic membrane tubules termed Salmonella-induced filaments or SIF. Here we report the first detailed ultrastructural analyses of the SCV and SIF by electron microscopy (EM), EM tomography and live cell correlative light and electron microscopy (CLEM). We found that a subset of SIF is composed of double membranes that enclose portions of host cell cytosol and cytoskeletal filaments within its inner lumen. Despite some morphological similarities, we found that the formation of SIF double membranes is independent from autophagy and requires the function of the effector proteins SseF and SseG. The lumen of SIF network is accessible to various types of endocytosed material and our CLEM analysis of double membrane SIF demonstrated that fluid phase markers accumulate only between the inner and outer membrane of these structures, a space continual with endosomal lumen. Our work reveals how manipulation of the endosomal membrane system by an intracellular pathogen results in a unique tubular membrane compartmentalization of the host cell, generating a shielded niche permissive for intracellular proliferation of Salmonella.
Author Summary
Salmonella enterica is an invasive, facultative intracellular bacterial pathogen. Within mammalian host cells, Salmonella inhabits a specialized membrane-bound compartment, the Salmonella-containing vacuole (SCV), redirects host cell vesicular transport and massively remodels the endosomal system. These activities depend on the function of a type III secretion system and its translocated effector proteins. Intracellular Salmonella induces several types of tubular compartments termed Salmonella-induced tubules (SIT), but the biogenesis and biological function of SIT is only partially understood. Our work combines live cell imaging with correlative light and electron microscopy to provide ultrastructural insight into SIT. We report that SIT emerge as single membrane tubules that convert into double membrane tubules entrapping cytosol and cytoskeletal filaments. Labeling of the endosomal compartment and cytochemistry demonstrate that the space between inner and outer SIT membrane is composed of internalized material and connected to Salmonella within the SCV. The effector proteins SseF and SseG translocated by intracellular Salmonella are essential for the conversion of single to double membrane SIT. These findings challenge current models for the intracellular lifestyle of Salmonella and the composition of its intracellular habitat.
Introduction
Bacterial pathogens have evolved sophisticated mechanisms to modify host cell functions in order to avoid antimicrobial defense or to use host cell-derived material for their own proliferation. Intracellular pathogens evade humoral immune responses of the host by hiding inside cells of the host organism, using these cells to support their own proliferation and to disseminate within the host organism [1]. These activities require the manipulation of the normal host cell processes to avoid killing by the host cell and to establish a replication-permissive intracellular niche.
One group of intracellular bacteria resides in specialized membrane compartments that derive from the endosomal system of the host cell. Salmonella enterica is a facultative intracellular pathogen that modifies eukaryotic host cells in order to establish a unique parasitophorous vacuole, the Salmonella-containing vacuole or SCV [2], [3]. The SCV is a membrane-bound compartment that allows the survival and replication of S. enterica in a variety of mammalian host cells. At later time points after infection, the SCV acquires certain characteristics of late endosomal/lysosomal compartments such as (i) the presence of a subset of Rab GTPases, such as Rab7, (ii) lysosomal glycoproteins (lgp), such as LAMP1, (iii) acidification, and (iv) juxtanuclear positioning. However, the SCV remains permissive for intracellular replication of Salmonella. Several studies investigated the interaction of the SCV with the host cell endosomal system and indicate that various types of interaction take place during the maturation of this specialized compartment [4]–[7]. One unique phenotype resulting from these interactions is the induction of long tubular membrane compartments extending from the SCV, termed Salmonella-induced filaments or SIF [8].
SIF were first observed in Salmonella-infected epithelial cells, but we extended this observation also to phagocytic cells [9]. SIF are characterized by presence of specific protein markers similar to those on the SCV membrane and exhibit dynamic properties. The formation of SIF in epithelial cells starts from 3–4 h after invasion by fusion events of the SCV with endosomal vesicles. These early SIF are highly dynamic tubules which often exhibit a thinner appearing part at the distal end, termed leading SIF (LS), in comparison to the proximal part, termed trailing SIF (TS). From 8 h post infection (p.i.) a complex tubular network is established which appears stable and less dynamic. [9], [10].
Despite a large body of work on the intracellular activities of Salmonella, the biogenesis and function of SIF are still enigmatic. In addition, recently distinct tubular membrane compartments have been identified induced by intracellular Salmonella: Golgi-derived Salmonella-induced SCAMP3 tubules (SIST) [11] and LAMP1-negative tubules (LNT) in cells infected with a sifA sopD2 double mutant strain [12]. Throughout this paper we will use the general term Salmonella-induced tubules (SIT) which does not discriminate between SIF, SIST, LNT or another (un)classified subtype of SIF. Characteristic features of SIT are summarized in Table 1.
Table 1. Features of Salmonella-induced tubules (SIT).
Type | Marker proteins | Time of formation p.i. (maximum) | Reference |
SIF (Salmonella-induced filaments) | lgp, Rab7, vATPase, LBPA, cholesterol | 3–16 h (8–16 h) | [4]–[12] |
SPI2-T3SS effectors | |||
SIST (Salmonella-induced SCAMP3 tubules) | SCAMP3 | 8–14 h (14 h) | [11] |
SPI2-T3SS effectors | |||
LNT (LAMP1-negative tubules) | vATPase, cholesterol | 3–16 (16 h) | [12] |
SPI2-T3SS effectors |
Of central importance for the intracellular lifestyle of Salmonella is the function of the type III secretion system (T3SS) encoded by Salmonella Pathogenicity Island 2 (SPI2). Intracellular Salmonella deploy the SPI2-T3SS to translocate a set of effector proteins across the membrane of SCV [2]. Collectively, these effector proteins enable the intracellular survival and proliferation of Salmonella. For the majority of SPI2-T3SS effectors the exact mode of action and molecular targets in the host cell remain unknown. However, some effectors are likely relevant for both, induction of specific intracellular phenotypes and systemic pathogenesis. Formation of SIF requires at least five Salmonella effector proteins, i.e. SifA, SseF, SseG, SopD2 and PipB2, and the integrity of the microtubule cytoskeleton [13], [14]. The most severe phenotype is mediated by the SPI2 effector SifA [15]. Mutant strains lacking SifA are highly attenuated in intracellular replication and systemic virulence. Bacteria deficient in sifA fail to induce SIF and escape into the cytoplasm of the host cell due to a loss of SCV membrane integrity [15]. SseF and SseG also contribute to the intracellular lifestyle, although the defects in intracellular replication of the corresponding mutant strains are less pronounced compared to sifA or SPI2-T3SS deficient strains.
The strict correlation between intracellular fitness of Salmonella and its ability to form SIF prompted us to investigate the nature of these tubular endosomal compartments in Salmonella-infected cells. We examined the biogenesis of the SCV and Salmonella-induced tubular compartments by a combination of confocal laser scanning microscopy (CLSM) of live infected cells, followed by ultrastructural analyses by transmission electron microscopy (TEM) and electron tomography (ET). Our observations based on correlative light and electron microscopy (CLEM) provide a novel view on the intracellular activities of Salmonella leading to unique compartmentalization of the host endosomal membranes and we propose new models for SIF biogenesis.
Results
Intracellular Salmonella induce various types of host cell membrane tubules
We previously reported the ultrastructure of tubular membrane compartments in connection with SCV [9]. In addition to SIF with the characteristic presence of lgp, recent studies revealed additional types of tubular membrane compartments in Salmonella-infected cells including SIST [11] and LNT [12]. Here we use the general term ‘Salmonella-induced tubules’ or SIT if no further distinction is possible.
For an overview of possible ultrastructural differences of SIT we first performed conventional TEM of Salmonella WT-infected HeLa cells (Figure 1). Ultrathin horizontal sections through flat-embedded cells revealed both, longitudinal and cross-sections through SIT. At the time points of sampling, i.e. 8–12 h p.i., the majority of intracellular WT Salmonella (82.7%, N = 208 bacteria) were contained within membrane compartments. These SCV enclosed one or more bacteria into a complex membrane organelle with a lumen enriched in electron-dense granules and multi-lamellar vesicles (Figure 1). Membrane tracing on cross-sections through the SCV revealed a continual ‘outer’ membrane of the SCV which encircled bacteria but also numerous membrane-enclosed bubble-like compartments within the lumen of the SCV (Figure S1). Although these compartments were reminiscent of cytosolic pockets enclosed within the complex 3D structure of the SCV, they may as well result from invaginations of the SCV ‘outer’ membrane.
Extended analyses of ultrathin sections by TEM revealed additionally a variety of SIT morphotypes and an unexpected membrane organization of the tubular compartments (Figure 1). Apart from very thin single membrane SIT of rather uniform diameter of 46±8 nm and moderately electron-dense content (Figure 1Ai), we also observed thicker single membrane SIT that appeared more electron-dense (Figure 1Bii, iii). The latter tubules were characterized by a lumen containing electron-dense granules and vesicles, reminiscent of the luminal content of late endosomes or endolysosomes [16], and will be referred to as type 1 SIT. Most frequently, we observed extended tubules with luminal content of low electron density (Figure 1Cvi, vii). These SIT were delimited by two adjacent membranes which we discriminate as outer and inner membrane. These structures will be referred to as type 2 SIT. Both type 1 and type 2 SIT were also found in the same cells, and in some sections, interconnection between both types of tubules was detected. From observations by light microscopy, Salmonella is known to induce tubular networks [8], [11], [12]. We identified and traced the observed tubular structures by TEM throughout serial sections of Salmonella WT-infected cells (about 100 sections per cell), indicating also a complex 3D network of SIT. Thus, quantification of the frequency of SIT phenotypes in ultrathin sections by TEM was not feasible given the complexity, size and 3D organization of SIT. However, inspection of TEM ultrathin sections allows an approximation of the frequency of SIT phenotypes. Sections of HeLa cells (N = 124 cells) infected with Salmonella WT for 8–12 h revealed that 13.7% of cells displayed type 1 SIT, 74.2% displayed type 2 SIT, and 6.5% of cells showed both SIT types.
Measurements of diameters revealed for type 1 SIT average diameters for single membrane tubules of 120±46 nm (N = 7 cells with 5 measurements per SIT) and for type 2 SIT, the average diameter of double membrane tubules was 221±65 nm (N = 30 cells with 5 measurements per SIT, Figure S2A). The mean distance between inner and outer membrane of the tubule was 31±12 nm. We observed that the diameter of type 2 SIT was rather constant over the segment present in one ultrathin section. Examples of longitudinal sections and cross sections through type 2 SIT are shown in Figure S2.
Type 2 SIT inner lumen contains cytosolic content and cytoskeletal filaments
The closer examination of type 2 SIT by conventional TEM indicated that the inner lumen of the double membrane tubules contains numerous ribosomes and occasionally also filamentous structures. Filaments of smaller and larger diameter were detected with a distinct morphological similarity to actin filaments and microtubules, respectively (Figure 2). We determined the diameter of the larger filaments as 22.05±2.29 nm (N = 15) which is consistent with the diameter of microtubules (22–24 nm) (Figure 2A–D) [17]. Microtubules were detected only in a subpopulation of sections through type 2 SIT, suggesting that their presence or absence may be related to a certain developmental stage of the tubules. The thinner filaments had diameters of less than 5 nm, but a precise measurement was not possible due to limits of resolution in 40–60 nm sections (Figure 2E). Based on the filament thickness and morphology in accordance with previous observations [17], we propose that the thinner filaments are F-actin microfilaments. Immuno-gold labeling of cytoskeleton in TEM sections was not successful, probably due to insufficient preservation. Thus, our conclusion of F-actin and microtubules within SIT so far is based on the typical ultrastructural morphology. For an unambiguous determination of the composition of the SIF lumen, our future work will make use of genetically encoded tags [18]. Co-localization of SIF and LNT with microtubules [9], [12] and F-actin (DC, KG, MH, unpublished data) was already observed, but light microscopy cannot reveal if cytoskeletal filaments are on the outside of SIT, or within the lumen. Examination of various ultrathin sections of HeLa cells (N = 124 cells) 8–12 h after infection with Salmonella WT revealed that 27.2% or 4.3% of type 2 SIT contain microtubules or F-actin filaments, respectively. The density of cytoskeletal filaments inside type 2 SIT was variable, but some compartments appeared filled with a large amount of filaments (Figure 2Ai). The ultrastructure-based localization of cytoskeletal filaments both outside [9] and inside type 2 SIT (this paper) clearly emphasizes their prominent role in the biogenesis of SIT.
These findings suggest that the interior space of type 2 SIT is either continuous with the host cell cytosol or represents a partial volume of cytosol enwrapped by double membranes during formation of the tubule.
SIF lumen is accessible to various types of endosomal content
In order to investigate the continuity between the lumen of SIT and endosomes, we probed the intracellular environment of Salmonella by pulse-chase experiments in combination with live cell imaging. Our previous analyses demonstrated that BSA-Rhodamine-conjugated gold nanoparticles are a useful experimental tool that efficiently accumulate and label endosomal compartments [19]. This tracer is also suitable for CLEM applications by virtue of electron-dense gold particles of defined size, as well as the possibility to use Rhodamine for photo-conversion of diaminobenzidine (DAB) [20]. Additionally, in order to obtain a moderate and consistent expression level of an endosomal membrane marker, we used lentiviral transfection to generate a HeLa cell line constitutively expressing LAMP1-GFP which also localizes to SIF. This cell line was indistinguishable from the parental cell line with respect to the intracellular phenotypes of Salmonella (Figure S3, Figure S4, Figure S5) and was therefore used in all microscopic approaches. For fluid tracer experiments, HeLa LAMP1-GFP cells were pulse-chased with BSA-Rhodamine-gold at various times prior or after the infection with Salmonella WT and analyzed by live cell imaging (Figure 3). Endocytosed BSA-Rhodamine-gold distributed rapidly within the network of SIF and all LAMP1-positive compartments were also positive for the fluid tracer. Compared to the positive control (co-localization rate of 78.5±1.3% and Pearson's correlation coefficient of 0.82±0.01), LAMP1-GFP and Gold-BSA-Rhodamine showed comparable high co-localization in either non-infected cells (co-localization rate of 80.22±6.7% and Pearson's correlation coefficient of 0.85±0.02) or cells post infection (e.g., at 8 h p.i., co-localization rate of 79.7±3.5% and Pearson's correlation coefficient of 0.74±0.02). We also observed the fluid tracer within the SCV, decorating the bacterial cell body. The intensity of Rhodamine fluorescence increased with the duration of the pulse and consequently with the amount of the marker accumulated in the endosomal system of the cell. In conclusion, these data show that SIF lumen is accessible to endosomal content and support our observation in TEM of the endosomal-like content of type 1 SIT (Figure 1B).
Correlative light and electron microscopy reveals identity of Salmonella-induced filaments
The precise interpretation of the SIF integrity requires the analysis of Salmonella infection in living cells [9], [21]. Therefore, we used the HeLa LAMP1-GFP cell line for live cell imaging of infected cells followed by processing for CLEM. This approach allowed us first to follow the integrity and dynamics of LAMP1-GFP-positive tubular structures in living infected cells, and then to investigate the ultrastructural features of the same tubular structures by TEM. We observed that at 8 h after infection with Salmonella WT all double membrane type 2 SIT were positive for LAMP1-GFP (Figure 4). Thus, we conclude that type 2 SIT are of late endosomal/lysosomal origin and are identical to the previously described SIF. Any similar tubular compartments were neither observed in non-infected HeLa cells (Figure S6), nor in cells infected with an ssaV-deficient strain unable to translocate SPI2-T3SS effector proteins (data not shown).
We next analyzed infected cells shortly after onset of SIF formation, i.e. 4–5 h p.i. (Figure 5, Figure S7). Previous work showed that SIF are highly dynamic at this early stage and undergo extension, branching and contraction [9], [10]. Furthermore, in living cells, we frequently observed connections between LAMP1-positive tubules of two kinds: (i) thinner tubules with weak fluorescence intensity often localized at the periphery of the cell and (ii), centrally localized thicker tubules with strong fluorescence intensity connected to SCV (Figure S5). This phenotype was reminiscent of the previously described leading SIF (LS) and trailing SIF (TS) [9], [10]. When observed by light microscopy LS extend further from the distal end of TS. Importantly, frequently detected gradual transitions of LS into TS suggest that they both represent one tubular structure undergoing morphological transition(s). We therefore set out to analyze these morphological features of WT-infected HeLa LAMP1-GFP cells by CLEM, additionally pulse-chased with BSA-Rhodamine. Our results indicated two types of SIF morphologies. SIF representing LS in light microscopy correlated with single membrane SIT of thinner diameter and electron-dense content, similar to type 1 SIT. These were often found in continuum with double membrane SIT of extended diameter and cytoplasmic content, similar to type 2 SIT, correlating with TS in light microscopy (Figure 5). Based on these observations we propose that the dynamic conversion of leading into trailing SIF observed by light microscopy, in fact corresponds to the conversion of a single membrane tubule (type 1 SIT) to a double membrane tubule (type 2 SIT). Consequently, the observed type 1 SIT or LS are of late endosomal/lysosomal origin and serve as precursor of type 2 SIT or TS, while both morphological structures represent LAMP1-positive SIF in Salmonella WT-infected cells.
Salmonella induces double membrane SIF in RAW264.7 macrophages
To test if the formation of double membrane SIF (type 2 SIT) is restricted to HeLa cells or a more general phenomenon, we analyzed Salmonella-infected RAW264.7 macrophages by live cell CLEM. First, a RAW264.7 cell line with stable expression of LAMP1-GFP was generated by lentiviral transfection and the transfection had no influence on the intracellular phenotypes of Salmonella (data not shown). To achieve a flat, adherent cell morphology for microscopic studies, the macrophages were stimulated with Interferon-γ (IFNγ). We first investigated non-infected RAW264.7 macrophages activated by IFNγ, since long tubular endosomal compartments were reported for phagocytic cells [22]. CLEM of non-infected activated RAW264.7 cells showed thin LAMP1-GFP-positive single membrane tubules that contain many small vesicles (Figure S8A–E). These tubular structures in RAW264.7 cells were sometimes extending throughout the entire cell. In infected RAW264.7 cells the LAMP1-GFP-positive SIF were identified by virtue of their connections to the SCV. These tubules were substantially thicker and with stronger LAMP1-GFP signal compared to LAMP1-GFP-positive tubules in non-infected cells. Macrophages were infected with stationary phase Salmonella to avoid invasion-induced pyroptosis, thus the onset of SIF formation in infected RAW264.7 macrophages is delayed compared to infected HeLa cells [9]. Accordingly, we adjusted time points for microscopic analyses. CLEM of activated and Salmonella WT-infected RAW264.7 LAMP1-GFP cells revealed single membrane tubules at 8 h p.i. (Figure S8F–J), comparable to type 1 SIT in HeLa cells at 4 h p.i., as well as double membrane tubules at 12 h p.i. (Figure 6), comparable to type 2 SIT in HeLa cells at 8 h p.i. Pulse-chase experiments with BSA-Rhodamine and subsequent photo-conversion of DAB in infected RAW264.7 macrophages showed similar results as for HeLa cells (data not shown). In summary, these data demonstrate the presence of type 2 SIT in RAW264.7 macrophages comparable to double membrane SIF in HeLa cells, and suggest that induction of double-membrane tubules by intracellular Salmonella is a common phenomenon.
Salmonella-induced double membrane tubules are distinct from autophagosomes
Double (and multiple-) membrane compartments are typically observed during the formation of autophagosomes [23], and autophagy has been reported as a host cell factor involved in the control of intracellular Salmonella [24]–[27]. We thus tested whether SIT are related to autophagosomes. Microtubule-associated protein 1 light chain 3 (LC3), a mammalian homolog of yeast ATG8, is a well-established marker of autophagy and its proteolytically processed form, LC3-II, associates with membranes of the phagophore, autophagosome and autolysosome [28], [29]. HeLa cells were transfected with GFP-LC3b, infected with Salmonella WT and the endosomal system was then labeled with fluorescent fluid-phase marker (Figure S9A). Epifluorescence microscopy of living cells showed that a small fraction of intracellular bacteria (app. 5–10%) was associated with LC3b, a finding in line with previous observations on the cytosolic presence of a subset of intracellular bacteria and the targeting of some of these bacteria by autophagy [30]. Starting at 3–4 h p.i., GFP-LC3b-transfected HeLa cells also showed the presence of SIT, but these were not associated with LC3b at all and the distribution of the GFP-LC3b signal was clearly distinct from the tubular arrangement of the endocytosed fluid tracer (Figure S9A). To further examine the possible involvement of autophagy, we inhibited ATG5, a key regulator of all known human ATG8 homologous [reviewed in 31]. Therefore HeLa LAMP1-GFP cells were transiently transfected with a plasmid encoding mCherry-ATG5-K130R, a dominant-negative form of ATG5 [32], [33]. Transfected cells were infected with Salmonella WT, analyzed by light microscopy and prepared for CLEM. Interestingly, CLSM revealed a reduction in SIF formation compared to non-transfected HeLa cells. Non-transfected HeLa cells infected by Salmonella WT showed 72.3±3.5% of infected cells with SIF formation. Salmonella WT-infected cells previously transfected with dominant-negative ATG5 revealed only 56.6±6.1% SIF formation (Figure S9B). This observation is consistent with work of Birmingham et al. [30], who investigated Salmonella-infected atg5−/− MEF. However, we observed no obvious changes in SIF morphology. Micrographs also clearly showed that LAMP1-GFP-positive SIF in HeLa cells transfected with mCherry-ATG5-K130R display a double membrane structure similar to type 2 SIT (Figure S9C–F). Based on these observations, we rule out that biogenesis of type 2 SIT is related to formation of autophagosomes and anticipate a distinct mechanism of double membrane formation.
The outer lumen of double membrane SIF is accessible for fluid phase markers
The observation of double membrane SIF raised the question of the origin of the SIF inner lumen and of the lumen between inner and outer membrane, termed SIF outer lumen. To analyze the lumen of SIF with ultrastructural resolution, we applied pulse-chase experiments with fluid-phase markers suitable for detection by both, CLSM and EM. Although Rhodamine-gold provided intense and uniform labeling of the SIF lumen (Figure 3), the frequency of gold NP in thin sections analyzed by TEM was rather low (<10 particles per SIF in a ultrathin section). As an alternative, we used Rhodamine for the UV light-induced photo-conversion of diaminobenzidine (DAB) [20]. The conversion (oxidation) of DAB leads to a precipitation of an alcohol-insoluble, granular polymer which, after further processing, becomes an electron-dense product detectable by TEM. Alternatively, we used the non-fluorescent horseradish peroxidase (HRP) as a fluid-phase marker catalyzing the conversion of DAB in presence of peroxide [34]. For this analysis, infected cells were first pulse-chased with either BSA-Rhodamine (without gold NP) (Figure 7) or HRP (Figure S10) to allow accumulation of the reagent within endocytic compartments including SCV and SIF, and then subjected to live cell imaging before fixation. The reaction with DAB was performed post fixation prior to sample processing for TEM.
If endocytosed BSA-Rhodamine or HRP interact with SIF, we anticipated that DAB reaction product is located either in the inner lumen, the outer lumen, or both lumen of the double membrane SIT. For LAMP1-GFP-expressing HeLa cells 8 h p.i. and pulse-chase with BSA-Rhodamine, we detected the Rhodamine signal in smaller LAMP1-positive spherical vesicles, as well as inside SIF and within the SCV (Figure 7J), thus showing the same distribution as fluorescent nanoparticles described in Figure 3. However, the correlation with TEM images revealed double membrane tubules with cytosolic content inside the inner lumen (i.e. type 2 SIT) and electron-dense DAB product inside the whole outer lumen. Higher magnification TEM clearly showed that electron-dense DAB product localizes inside the SCV with direct contact to Salmonella and inside the outer lumen of double membrane SIF, while the inner lumen was virtually devoid of the marker (Figure 7F).
Comparable results were obtained using HRP. Since no fluorescence signal is present for HRP as a marker, the DAB product was aligned using bright field microscopy. CLEM analysis of infected HeLa LAMP1-GFP cells pulse-chased with HRP also revealed DAB product inside the outer lumen of double membrane SIF (type 2 SIT) and within the SCV at 8 h p.i. (Figure S10).
Next, we analyzed the early stage of Salmonella infection to test if DAB product localizes within leading SIF (LS). CLEM of HeLa cells 4 h p.i. revealed LAMP1-GFP-positive single membrane SIF (type 1 SIT or LS), completely filled with the DAB product (Figure S11). In conclusion, these results indicate that after the conversion of single membrane tubules (type 1 SIT, LS) to double membrane tubules (type 2 SIT, TS), the endocytosed content of LS eventually accumulates inside the outer lumen of TS.
Formation of the double membrane SIF is dependent on the function of SPI2-T3SS effectors SseF and SseG
We have previously reported that mutant strains deficient in SPI2-T3SS effector proteins SseF or SseG induce the formation of SIF with altered morphology [35], i.e. less intense labeling by fluid phase markers and LAMP1-GFP fluorescence, thinner appearance and higher susceptibility to fragmentation by chemical fixation with para-formaldehyde (PFA). PFA-fragmented SIF in sseF or sseG-infected HeLa cells are also known as pseudo-SIF [21]. We found that tubular membrane compartments induced by the sseF or sseG strain were maintained after fixation with glutaraldehyde (GA) used conventionally for TEM. Compared to PFA-fixation of sseF-infected HeLa cells with 67.6±5.1% pseudo-SIF formation, fixation by GA resulted in 4.3±2.1% pseudo-SIF and 95.7±2.1% continuous SIF, as judged by light microscopy (N = 100 cells, 3 replicates). However, SIF in sseF-infected cells appeared more heterogeneous in morphology in ultrastructure and were reminiscent of LS observed at early time points of infection (Figure 5). CLEM revealed that SIF in sseF-infected HeLa LAMP1-GFP cells at 8 h p.i. were delimited by a single membrane with electron-dense content (Figure 8), like type 1 SIT. The mean diameter of SIF in sseF-infected cells was 107±18 nm (N = 6 cells with 5 measurements per SIF). This diameter is less than a half of the mean diameter of the double membrane SIF (221±65 nm) but in the range of the diameter of single membrane SIF (120±46 nm, see above).
We next performed CLEM of sseF-infected HeLa LAMP1-GFP cells after pulse-chase labeling with BSA-Rhodamine followed by DAB photo-conversion. TEM analysis of SCV-derived membrane tubules in these cells revealed that electron-dense DAB product localizes inside the entire lumen of the single membrane SIF at 8 h p.i. (Figure S12). CLEM experiments with HRP showed a similar phenotype (data not shown). In cells infected with the sseF-deficient strain complemented with WT sseF, the SIF double membrane phenotype was restored (Figure S13). An sseF strain expressing episomal sseF Δ200–205 was previously reported to be unable to induce normal SIF [36] and we found that cells infected with sseF strain expressing sseFΔ200–205 contained only thinner single membrane SIF (Figure S14). Our previous work showed that a defect in sseG phenocopies the sseF mutation. CLEM analyses of cells infected with the sseG-deficient strain showed results similar to the sseF strain, since sseG-infected cells displayed single membrane SIF with electron-dense content (Figure S15).
The SPI2-T3SS effector protein SifA has a key role in virulence since a sifA-deficient strain is highly attenuated in systemic virulence and intracellular replication. The sifA strain fails to induce SIF and loses the SCV membrane during intracellular replication, thereby escaping into the cytoplasm [15]. Interestingly, Boucrot et al. [37] showed that a transient ectopic expression of SifA in epithelial cells leads to LAMP1-positive aggregations and also thin SIF-like tubular structures. We investigated the ultrastructure of SifA-induced SIF-like tubules in non-infected HeLa cells co-transfected with LAMP1-mCherry and GFP-SifA by CLSM and CLEM. CLSM indicated that 9.3±2.5% of co-transfected HeLa cells showed a SIF-like phenotype (Figure S16A), compared to 15±5% reported before [37]. Micrographs of the observed thin LAMP1-mCherry and GFP-SifA-positive SIF-like structures clearly show single membrane tubules (Figure S16B–E), comparable to type 1 SIT, but much thinner (41±10 nm). Thus, SifA appears to be sufficient for the formation of LAMP1-positive single membrane tubules in uninfected HeLa cells, but is not sufficient to induce double membrane tubules. In summary, our results show that the effector proteins SseF and SseG are not required for formation of single membrane SIF (type 1 SIT), but are essential for biogenesis of double membrane SIF (type 2 SIT), while ectopic expression of SifA is sufficient to induce single membrane tubules.
The spatial organization of SCV and SIT
Finally, we addressed the complexity of SCV and SIT membrane organization by ET to reveal the ultrastructure of these compartments in 3D. HeLa cells were infected with WT Salmonella, fixed 10 h p.i. and 300 nm sections were used to generate tilt series from −60° to +60°. This approach identified Salmonella inside SCV with connecting SIT (Figure 9A, B, D, E).
The 3D reconstruction of partial cell volumes revealed both types of SIT previously observed by TEM on ultrathin sections: (i) single-membrane delimited SIT with a lumen containing electron-dense granules and multi-lamellar vesicular structures (type 1 SIT) (Figure 9A, Movie S2, Figure 9B, Movie S3, Figure 9C, Figure 9D, Movie S5, Movie S6), and (ii) double-membrane delimited SIT with a hollow lumen containing cytoplasmic components (type 2 SIT) (Figure 9C, Movie S4, Figure 9E, Movie S7, Movie S8, Figure 9F, Movie S9, Movie S10). In addition to the complexity of membrane folding within lumen of SIF, tomograms also revealed structural continuity between distant portions of SIF which otherwise appeared as separate structures on ultrathin sections. Interestingly, we also found branched SCV-derived tubular membrane structures that appeared as intertwined type 1 and type 2 SIT (Figure 9C, Movie S4). This once more suggests that the two structurally distinct membrane tubules may represent different developmental stages, a process we described earlier as leading-to-trailing SIF phenotype during dynamic membrane remodeling in living cells [9], and in this study as a possible conversion of single membrane tubules (type 1 SIT, LS) to double membrane tubules (type 2 SIT, TS).
Closer inspection of membrane arrangement within type 2 SIT emerging from the SCV revealed that both, inner and outer membrane, are in continuum and that Salmonella, together with other endosomal content resides between these two membranes (Figure 10A–C, Movie S11, Movie S12). Volume rendering of the distal end of the type 2 SIT disclosed that the inner membrane can enwrap portions of cytoplasm including electron-dense ribosomes. The tip of this SIT was captured within the data set of the tilt series and the 3D-rendering indicates that the tip of the captured SIT is closed (Figure 10D–F, Movie S13, Movie S14). These findings further support our hypothesis that the inner lumen of type 2 SIT, at a certain stage of SIT development, is in continuum with the cytoplasm before it is compartmentalized, while the space between the inner and outer membrane of these structures is the bona fide luminal space of SCV/SIT containing endocytosed cargo and bacteria.
Discussion
To our knowledge, this is the first systematic ultrastructural analysis of the intracellular environment of Salmonella in host cells and the fine structure of host cell compartments modified by activities of intracellular Salmonella. Our approach used combinations of live cell imaging, TEM of ultrathin sections, EM tomography and cytochemistry to reveal various novel aspects of Salmonella-driven manipulation of the host cell endosomal system. We anticipate that current models for the intracellular lifestyle of Salmonella have to be revised due to the findings reported in this study.
The limit of spatial resolution in light microscopy does not allow to obtain sufficient details in the organization of SCV and SIF, as for instance the distinction of single, double or multiple membranes forming these compartments. Consequently, the interpretation of presence or absence of canonical markers of the endosomal maturation has to be made with care. For example, given that SIF are composed of two membranes, different forms of biogenesis could explain the presence of lysosomal glycoproteins in SIF membranes. The marker may be located i) in the inner and outer membrane (both membranes are derived from late endosomes or lysosomes), ii) only in the outer membrane (outer membrane derived from late endosomes or lysosomes, origin of inner membrane is different), or iii) only in the inner membrane (situation inverse to ii). The data shown in this communication clearly highlight the importance of ultrastructural analyses in addition to analyses by light microscopy.
Besides new insight into the complexity of SCV membrane arrangement, our study revealed for the first time two morphologically distinct types of Salmonella-induced tubules (SIT) in Salmonella-infected epithelial cells and macrophages: (i) type 1 SIT, delimited by a single membrane with a lumen containing electron-dense granules and vesicles, reminiscent of the luminal content of late endosomes, endolysosomes or in part lysosomes [16], and (ii) type 2 SIT, composed of two membranes with the inner lumen containing host cell cytosol and the outer lumen containing the bacteria and endocytosed material. CLEM showed that both type 1 and 2 SIT are dynamic, lgp-positive membranes, thus identical with the previously described Salmonella-induced filaments or SIF (Figure 4, Figure 5, Figure S11). Moreover, type 1 SIT were identified as the earlier described leading SIF (LS) and type 2 SIT as the appropriate trailing SIF (TS) (Figure 5). Thus, we suggest that dynamic conversion of leading to trailing SIF corresponds to the conversion of single membrane tubules (type 1 SIT) to double membrane tubules (type 2 SIT) and that type 1 SIT represent developmental precursors of type 2 SIT.
Double membrane compartments are typical for autophagosomes. Double membrane formation has been reported during the maturation of Coronaviruses [38], [39], or Hepatitis C virus [40] whereby an LC3-associated, but autophagy-independent recruitment of host membrane was considered. It is well known that autophagy targets Salmonella that has been released into host cytosol due to loss of SCV integrity [25], but we showed that double membranes of type 2 SIT are formed independently from autophagy.
How can we explain the biogenesis of double membrane SIF with internal cytoskeletal elements? Figure 11 shows our working model with key events of SIF biogenesis. After invasion of host cells (Figure 11A), Salmonella within an early SCV start to translocate SPI2-T3SS effector proteins and to manipulate the host cell endocytic system (Figure 11B). We propose that single membrane SIF (type 1 SIT) emerge by tubulation of SCV membranes along cytoskeletal filaments (Figure 11C). This tubulation occurs longitudinal by fusion processes of endosomes and we and others previously reported the dynamic features of SIF in this initial phase of intracellular life of Salmonella [9], [10]. Our model implies that membrane extension also occurs laterally, resulting in the formation of a double membrane sheath enclosing microtubules, F-actin and portions of cytosol (Figure 11D, M). Since SIF cross sections and tomograms demonstrate continuity of SIF inner and outer membrane, we postulate that such a process ultimately results in membrane fusion and formation of double membrane SIF (type 2 SIT) (Figure 11E, M).
How does the transition from early, single membrane SIF (type 1 SIT, LS) to double membrane SIF (type 2 SIT, TS) occur? In light microscopy, the dynamic formation of thin LS with low LAMP1-GFP intensity, and bolder TS was observed [9], [10], see Figure 11F for an example. We think this observation is in line with a zipper-like mechanism of membrane fusion depicted in Figure 11O. The conversion into double membrane SIF is incomplete in the early stage of SIF formation, thus explaining the reversion of LS to TS and back. The limited resolution of light microscopy does not allow to trace the proposed zipper-like fusion events in living cells and the molecular mechanism underlying the membrane fusion has to be revealed by future work.
What is the origin of SIF membranes and luminal material? Previous studies indicated the interaction of the SCV with early and late endosomes [6], as well as with exocytic vesicles [7]. We demonstrated that SIF networks are in continuous interchange with endocytosed material, as observed for fluid tracers and fluorescent nanoparticles ([19], this study). The multiple interactions may result in a continuous network of SIF lumen with a very large volume connected to SCV (Figure 11G, H). Simple TEM micrographs in this study revealed electron-dense granules and vesicles for single membrane SIF, indicating a luminal content comparable to late endosomes, endolysosomes or, in part, lysosomes. CLEM experiments with HRP or BSA-Rhodamine demonstrated that the single membrane SIF lumen incorporates these fluid tracers and our model implies that, upon conversion into double membrane tubules, this luminal content represents the content of the outer lumen of double membrane SIF that is also in contact to Salmonella within the SCV. We propose that Salmonella within the SCV have a continuous interchange with endocytosed material such as medium components, but remain segregated from cytosolic components of the host cells that are entrapped in the inner SIF lumen of double membrane SIF (Figure 11H). This model clearly supports a role of SIF for the nutritional supply of Salmonella within the SCV.
The high abundance of lgp such as LAMP1 suggests a late endosomal/lysosomal origin of SIF membranes, however, the exposure of Salmonella within the SCV to antimicrobial effectors appears to be limited [4]. Recent work by the Holden group [41] demonstrated that by action of the effector protein SifA, intracellular Salmonella actively interfere with the proper activation and delivery of lysosomal hydrolases such as Cathepsin D to the SCV. Furthermore, there is evidence for distinct routes of delivery of lysosomal membrane material including lgp (‘LAMP carriers’) and the lysosomal hydrolases to late endosomes (‘MPR carriers’) [42]. By selectively recruiting ‘LAMP carriers’ and/or avoidance of ‘MPR carriers’, intracellular Salmonella would be able to generate extensive lgp-positive membrane compartments without exposure to lysosomal hydrolases. A further explanation could be the dilution of antimicrobial effectors in a large volume of SCV continual with volume of extensive network of SIF (Figure 3, [19]). _ENREF_16Luminal content of vesicles fusing with the SCV or SIF could be rapidly mixed with the luminal content of SIT, resulting in decreased concentrations of antimicrobial activities. Indeed, we also observed a decreased acidification of SCV if connections to SIF were present (YZ, MH, unpublished observations). This model may also explain the previous controversial observation of low degree of delivery of lysosomal enzymes to the SCV [4]. We clearly detect delivery of fluid tracers (NP, BSA-Rhodamine, HRP, etc.) to SCV and SIF. However, rapid dilution of incoming tracers within the luminal space of the network may explain why prolonged exposures (longer pulse times) are required to obtain detectable signals.
Which molecular mechanisms lead to fusion events resulting in double membrane SIF? Induction of SIF is dependent on function of the SPI2-T3SS and a subset of effector proteins, predominantly SifA, SseF, SseG, SopD2 and PipB2. Most likely, host cell-intrinsic mechanisms are manipulated by activities of SPI2-T3SS effectors. The interaction of SifA with SKIP is an excellent example [41], [43], [44]. SifA is essential for the induction of SIT and sifA mutant strains are defective in maintenance of the SCV (Figure 11I, J). Expression of GFP-SifA in uninfected epithelial cells leads to LAMP1-positive aggregations and also thin SIF-like tubular structures [37]. Here, we showed by CLEM that these SIF-like tubular structures represent single membrane tubules (Figure S16). Therefore, we propose that the SPI2-T3SS effector SifA could be sufficient for the formation of single membrane SIF. Yet action of SifA is insufficient to induce double membrane SIF. The exact mechanism of membrane fusion and longitudinal tubulation caused by SifA has to be examined in future work. Interestingly, mutant strains lacking SseF and SseG are attenuated in intracellular replication [35]. In sseF-and sseG-infected HeLa cells only thin SIF are formed (Figure 11K, L) and our CLEM analysis revealed single membrane SIF for both mutants (Figure 8, Figure S12, Figure S15). Consequently, we propose that SseF and SseG are the key SPI2-T3SS effectors involved in the lateral tubulation of single membrane SIF and the final membrane fusion leading to double membrane SIF. For SseF and SseG, the host cell targets appear less clear, the target candidates for SseF and SseG [45], [46] do not indicate involvement in membrane fusion. The molecular mechanism behind SseF-and SseG-mediated membrane remodeling still remains open, but our previous study [47] suggested that SseF is involved in Dynein recruitment to the SCV membrane, what is likely essential for extension of SIF from SCV along microtubules. The absence of double membrane SIF after infection with sseF- or sseG-deficient Salmonella may also be explained by a missing direct interaction of these effectors after membrane insertion. SseF is an integral protein of host endosomes [36] and a direct interaction with SseG has been demonstrated [48]. This model would imply that Salmonella, by means of the SPI2-T3SS, transfers an autonomous membrane fusion machinery into the host cell in order to induce extensive membrane aggregations resulting in double membrane compartments. Such novel function of T3SS effectors will require detailed experimental investigation.
Alternative models for biogenesis of SIF are shown in Figure 11N, P, Q. An inner tubule may also be formed by fusion of invaginated membrane vesicles located within the single membrane SIF (Figure 11N, Q). We observed some single membrane SIF with a multivesicular content (Figure 1B, Figure 8A–D). However, we neither observed invagination processes nor intermediate phases of fusion processes of the intraluminal vesicles inside single membrane SIF. Furthermore, the model proposed in Figure 11N, Q fails to explain mechanistically the enclosure of microtubules and F-actin, and we consider this model as less likely. Alternatively, vesicles moving along microtubules together with single membrane SIF could be entrapped the same way as cytoskeleton during the double membrane formation and afterwards the inner tubule could grow due to fusion events of the vesicular content with the SIF inner membrane from the inside (Figure 11M, P). Such double membrane SIF with vesicles inside the inner lumen were also observed in micrographs for early time points of Salmonella infection (Figure S7). At later time points after infection, vesicles were seldom observed inside the SIF inner lumen, indicating their disappearance, probably due to fusion with the inner membrane. It is also possible that events depicted in Figure 11O and P occur simultaneously, since both originate from lateral tubulation (Figure 11M).
The data reported here give rise to a number of further questions and experimental challenges regarding the intracellular lifestyle of Salmonella. The most important question is: How could intracellular Salmonella benefit from the formation of a double membrane SIF network? We consider three consecutive scenarios: i) By means of the SPI2-T3SS effector SifA intracellular Salmonella induce the formation of single membrane tubules extending from the SCV. This extensive tubular SIF network may generate a compartment in which incoming endocytic cargo accumulates and bactericidal lysosomal content is diluted. Such mechanism would provide nutrients for Salmonella within the SCV, but also decrease the local concentration of antimicrobial activities. For the dilution effect vesicles with various types of luminal content have to fuse to the SIF network. ii) Transport of both, endocytic and exocytic vesicles towards SCV and SIF and eventual fusion is critical for the successful intracellular lifestyle of Salmonella. A large number of fusion events may result in excessive amounts of membrane material at the SCV/SIF and dramatically increase their surface area. Here we speculate that a shortage of solid content within the volume of SCV/SIF causes insufficient physical support to maintain their circular profile and, together with a surplus of membrane, leads to a structural collapse of these membrane compartments. This hypothesis is supported by our findings that SCV membranes often fold into double-membrane curved sheets and invaginate or extend into SIF tubules (examples in Figure 1C, Figure 10C). Our model suggests how single membrane SIF (type 1 SIT) can extend both, longitudinally and laterally along microtubules and eventually wrap up and close to form double membrane SIF (type 2 SIT). It remains to be clarified to which extent and how this membrane rearrangement is controlled by Salmonella, e.g. through the action of SPI2-T3SS effectors SseF and SseG. iii) The formation of double membrane SIF through the entrapment of cytosol and especially the entrapment of cytoskeletal filaments into double membrane SIF will result in a stabilized tubular network. Within double membrane SIF, F-actin and microtubules are segregated from exchange with cytosolic components. The previously observed phenotype of microtubule bundling in Salmonella-infected cells may be explained by accumulation of microtubules inside double membrane SIF [14]. Furthermore, the accumulation of cytoskeleton within double membrane SIF could explain the previous observation of decreasing dynamics of SIF at later time points after infection [9], [10]. The stabilized SIF network would allow the SCV to maintain the juxtanuclear, Golgi-associated position that is essential for efficient intracellular proliferation [5], [47], [ reviewed in 49]. A stabilized SIF network would ensure the supply of Salmonella within the SCV with endocytosed nutrients and probably nutrients delivered by fusion events of distinct vesicles.
Finally, the morphology and function of other SIT like SIST and LNT remains an open question. In our study performed on HeLa or RAW264.7 cells at early (4–5 h) or late (8–12 h) time points p.i., all tubular structures connected to SCV observed were LAMP1-GFP-positive. For SIST, formation at very late time points after infection of HeLa cells was described [11], thus our analyses most likely did not cover SIST formation. The highest number of LNT was reported for the infection of HeLa cells with a sifA sopD2 double mutant strain [12], which was not analyzed here. Future work has to reveal the details of the complex tubular membrane compartments induced by intracellular Salmonella.
Materials and Methods
Bacterial strains and growth conditions
Salmonella enterica serovar Typhimurium strain NCTC12023 was used as wild-type strain and isogenic mutant strains used in this study are listed in Table 2 [15], [35], [50]. For complementation, the sseF mutant strain was used harboring PsseA sscB sseF::HA or PsseA sscB sseF Δ200–205::HA [36]. If required for detection in live cell imaging, the strains harbored pFPV25.1 [51], pFPV-mCherry/2 [10] or pETcoco1-PrpsM-mCherry2 [52] for constitutive expression of GFP or mCherry, respectively. Bacteria were grown in LB broth at 37°C with aeration.
Table 2. Bacterial strains and plasmids used in this study.
Designation | relevant genotype | Reference, GenBank ID |
S. enterica serotype Typhimurium strains | ||
NCTC12023 | wild type | lab collection |
P2D6 | ssaV::mTn5 | [50] |
P3H3 | sifA::mTn5 | [15] |
HH107 | ΔsseF::aphT | [54] |
HH108 | ΔsseG::aphT | [54] |
Plasmids | ||
pEGFP-C1 | Clontech | |
pmCherry-C1 | Clontech | |
pFPV25.1 | [51] | |
pFPV-mCherry/2 | [10] | |
p3589 | pETcoco1 const. mCherry | [52] |
p3432 | LAMP1-eGFP | [9] |
p3451 | LAMP1-mCherry | this study |
pBABEpuro GFP-LC3 | GFP-LC3b | [55], Addgene 22405, U05784 |
pmCherry-ATG5 | ATG5 | [33], Addgene 13095, AB048349 |
pmCherry-ATG5-K130R | ATG5-K130R | [33], Addgene 13096 |
p3942 | GFP::sifA in pEGFP | this study |
p2643 | PsseA sscB sseF::HA | [36] |
p3349 | PsseA sscB sseF Δ200–205::HA | [36] |
Cell lines and cell culture
For all experiments the non-polarized epithelial cell line HeLa (American Type Culture Collection, ATCC no. CCL-2) was used. HeLa cells were cultured in Dulbecco's modified Eagle's medium (DMEM) containing 4.5 g×l−1 glucose, 4 mM stable glutamine and sodium pyruvate (Biochrom) and supplemented with 10% inactivated fetal calf serum (iFCS) (Sigma-Aldrich) at 37°C in an atmosphere containing 5% CO2 and 90% humidity. The Lentivirus-transfected stable HeLa cell line expressing LAMP1-GFP was cultured under same conditions.
The murine macrophage-like cell line RAW264.7 (ATCC no. TIB-71) stably transfected with LAMP1-GFP via Lentivirus transfection was cultured in DMEM containing 4.5 g×l−1 glucose and 4 mM stable glutamine supplemented with 6% iFCS at 37°C in an atmosphere containing 5% CO2 and 90% humidity. For activation of RAW264.7 cells 7.5 ng×ml−1 IFNγ (BD Heidelberg) was added to the cell culture medium 24 h before infection. Prior to infection the cells were provided with fresh medium without IFNγ.
HeLa cells transfection
HeLa or HeLa LAMP1-GFP cells were cultured for one day in various culture vessels depending on the experimental setup and transfected with FUGENE HD reagent (Promega) according to manufacturer's instruction. In brief, 0.5–2 µg of plasmid DNA were solved in 25–100 µl DMEM without iFCS and mixed with 1–4 µl FUGENE reagent (ratio of 1∶2 for DNA to FUGENE). After 10 min incubation at room temperature (RT) the transfection mix was added to the cells in DMEM with 10% iFCS for at least 18 h. Before infection the cells were provided with fresh medium without transfection mix.
Host cell infection
For infection of HeLa or HeLa LAMP1-GFP cells, Salmonella strains were grown in LB broth overnight (ON), diluted 1∶31 in fresh LB and subcultured for 3.5 h in order to induce maximal SPI1-dependent invasion. The infection of HeLa cells was performed at different multiplicities of infection (MOI) for 25 min. RAW264.7 LAMP1-GFP cells were infected with ON cultures of Salmonella strains for 25 min. Subsequently, cells were washed thrice with PBS and incubated for 1 h with medium containing 100 µg×ml−1 gentamicin (Applichem) to kill non-invaded bacteria. Finally the medium was replaced by medium containing 10 µg×ml−1 gentamicin for the rest of the experiment.
Fluid-phase marker pulse-chase and DAB conversion
Fluid phase markers Gold-BSA-Rhodamine and BSA-Rhodamine were synthesized as described before [19] and applied to the cells after Salmonella infection at various time points prior to imaging. Co-localization analyses were performed using Leica LAS AF software (Leica, Wetzlar, Germany). As positive control, HeLa cells simultaneously pulse-chased with Dextran-Alexa Fluor 488 (Invitrogen) and Dextran-Alexa Fluor 568 (Invitrogen) were used. The same threshold was applied to each dataset for LAMP1-GFP and Gold-BSA-Rhodamine to calculate co-localization rates and Pearson's correlation coefficient (Imaris, Bitplane).
For 3,3′-diaminobenzidine tetrahydrochloride (DAB, Sigma) as TEM marker, cells were pulse-chased for indicated periods of time with 400 µg×ml−1 BSA-Rhodamine or 10 mg×ml−1 horseradish peroxidase (HRP, Type IV, Sigma) in complete DMEM medium. After live cell imaging of a region of interest (ROI) by CLSM, the cells were fixed and blocked as described in ‘Sample preparation for CLEM’. For the DAB conversion fixed cells were covered with freshly-prepared ice-cold 1 mg×ml−1 DAB in 0.2 M HEPES buffer. For BSA-Rhodamine, the ROI was viewed again by CLSM and DAB photo-conversion was started by irritating the ROI with blue light (Xenon lamp, full power) until a brown DAB polymer was visible by eye. For HRP the DAB conversion was initialized by adding H2O2 to a final concentration of 0.01% for 2 min in the dark. After DAB conversion in both cases, the DAB solution was removed and the cells were washed several times in HEPES buffer. The HRP-fed cells were checked by light microscopy for DAB conversion. Subsequently, the samples were further processed for TEM as described in ‘Sample preparation for CLEM’.
Live cell imaging
For live cell imaging DMEM was replaced by imaging-medium consisting of Minimal Essential Medium (MEM) with Earle's salts, without NaHCO3, without L-glutamine and without phenol red (Biochrom) supplemented with 30 mM HEPES (4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid) (Sigma-Aldrich), pH 7.4. The imaging studies were performed using the confocal laser-scanning microscope (CLSM) Leica SP5 equipped with an incubation chamber maintaining 37°C and humidity during live cell imaging. The software LAS AF (Leica, Wetzlar, Germany) was used for setting adjustment, image acquisition and image processing. At various time points post infection images were acquired with the 100× objective (HCX PL APO CS 100×) (Leica, Wetzlar, Germany) and the polychroic mirror TD 488/543/633 for the three channels GFP and mCherry/Rhodamine and DIC. A permanent LAMP1-GFP expressing HeLa cell line was generated by lentiviral transfection as described in Text S1. We confirmed that intracellular phenotypes of Salmonella were identical to those observed in transiently LAMP1-GFP infected HeLa cells.
Analysis of autophagy
HeLa cells (2.5×104) were seeded in eight well chamber slides (Ibidi), allowed to adhere overnight, and subsequently transfected with plasmid GFP-LC3b (Addgene, pBABEpuro GFP-LC3). The next day, cells were infected with WT Salmonella at an MOI of 100. Gold- Rhodamine nanoparticles were pulsed at 3 h p.i. for 1 h in order to indicate the Salmonella-induced tubular structures. Living cells were imaged at various time points post infection to track the co-localization of GFP-LC3b with Salmonella or Salmonella-induced tubular structures. As control for induction of autophagy by starvation, transfected HeLa cells were washed thrice with PBS and incubated in PBS at 37°C for 1 h.
Sample preparation for CLEM
HeLa LAMP1-GFP cells (1×105) or RAW264.7 LAMP1-GFP cells (1.5×105) were seeded in a petri dish with a gridded coverslip (MatTek, Ashland, MA) two days prior to the infection with Salmonella. One day before infection HeLa cells were transfected, if necessary, and RAW264.7 cells were activated by IFNγ. After the infection with an MOI of 75, if required, cells were pulse-chased with fluid-phase markers for indicated periods of time post infection. At indicated time points after infection, a ROI was observed by live cell imaging and cells were fixed as fast as possible directly on stage with pre-warmed 2.5% glutaraldehyde (Electron Microscopy Sciences) in buffer (0.2 M HEPES, pH 7.4, 5 mM CaCl2) for 1 h at 37°C. After rinsing the cells several times in buffer, unreacted glutaraldehyde was blocked by 50 mM glycine in buffer for 15 min, followed by rinses in buffer. Post-fixation was performed with 2% osmium tetroxide (Electron Microscopy Sciences) in buffer containing 1.5% potassium ferricyanide (Sigma) and 0.1% ruthenium red (Applichem) for 1 h at 4°C in the dark. After several washing steps the cells were dehydrated in a cold graded ethanol series and finally one rinse in anhydrous ethanol and two rinses in anhydrous acetone at room temperature. The gridded coverslip was removed from the Petri dish and cells were infiltrated and flat-embedded in mixes of acetone and EPON812 (Serva). During the removal of the gridded coverslip from the polymerized EPON block the engraved coordinates were transferred to the EPON surface and allowed trimming around the ROI. Serial 70 nm sections were cut with an ultramicrotome (Leica EM UC6) and collected on formvar-coated EM copper grids. After staining with uranyl acetate and lead citrate, cells were observed with TEM (Zeiss EFTEM 902 A), operated at 80 kV and equipped with a 2K wide-angle slow-scan CCD camera (TRS, Moorenwies, Germany). Images were taken with the software ImageSP (TRS image SysProg, Moorenwies, Germany). For image analysis, software packages LAS AF (Leica. Wetzlar), ImageJ (http://rsbweb.nih.gov/ij/) and Imaris (Bitplane, Zürich) were used. Stitching and overlay of CLSM and TEM images was done using Photoshop 5.5 (Adobe).
High pressure freezing and freeze substitution
For superior membrane preservation, samples were processed by high pressure freezing-freeze substitution (HPF-FS). Cells were grown in glass-bottom dishes (MaTek Corp.) on top of sapphire discs with a carbon finder-grid mask and coated with poly-L-lysine. At appropriate time post infection with MOI of 100, the dishes were processed directly for HPF as follows: Discs were removed from media, placed between hexadecane-treated aluminum specimen carriers with a 0.1 mm cavity and immediately transferred to LEICA HP010 holder and processed by HPF. Discs were then transferred from liquid nitrogen to the cryovials containing freeze-substitution medium (1% OsO4 and 0.2% uranyl acetate in Acetone) and then to FS device (LEICA AFS1) for FS processing with final embedding in EPON.
EM and EM tomography
Thin-sections were post-stained with 2% lead citrate in water and examined using a Morgagni electron microscope (FEI). Thick sections (300 nm) of HPF-FS samples were placed on a slot grid covered with a formvar film and decorated with 10 nm protein-A gold particles on both sides for image alignment. Grids were placed in a high-tilt holder (Fischione Model 2020) and dual-axis ET were carried out using a Tecnai F30 (FEI) electron microscope (operated at 300 kV) equipped with a field emission gun and a 4084×4084 pixels CCD camera (Eagle, FEI). Tomographic tilt ranges were typically from +60° to −60° with an angular increment of 1° pixel size ranging from 0.5 to 1 nm. Alignments, 3D reconstructions, and merging of serial tomograms were done with IMOD software suite [53]. The volume segmentations were performed with the Amira 4.1 visualization package (Visage Imaging, Berlin, Germany).
Supporting Information
Acknowledgments
We like to thank Dr. Jörg Deiwick and Dr. Hans-Peter Schmitz for support in generation of lentiviral transfected HeLa cells and Alexander Kehl for critical reading of the manuscript. We gratefully acknowledge Dr. Jayanta Debnath and Dr. Roberta Gottlieb for providing GFP-LC3 and ATG5 plasmids, respectively.
Funding Statement
This work was funded by the DFG by grant HE1964/18-1 and SFB944 project Z. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
References
- 1.Schaible UE, Haas A, editors (2009) Intracellular Niches for Microbes: A Pathogens Guide Through the Host Cell. Weinheim: Wiley-VCH. [Google Scholar]
- 2. Figueira R, Holden DW (2012) Functions of the Salmonella pathogenicity island 2 (SPI-2) type III secretion system effectors. Microbiology 158: 1147–1161. [DOI] [PubMed] [Google Scholar]
- 3. Ibarra JA, Steele-Mortimer O (2009) Salmonella - the ultimate insider. Salmonella virulence factors that modulate intracellular survival. Cell Microbiol 11: 1579–1586. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 4. Garcia-del Portillo F, Finlay BB (1995) Targeting of Salmonella typhimurium to vesicles containing lysosomal membrane glycoproteins bypasses compartments with mannose 6-phosphate receptors. J Cell Biol 129: 81–97. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 5. Salcedo SP, Holden DW (2003) SseG, a virulence protein that targets Salmonella to the Golgi network. EMBO J 22: 5003–5014. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 6. Drecktrah D, Knodler LA, Howe D, Steele-Mortimer O (2007) Salmonella trafficking is defined by continuous dynamic interactions with the endolysosomal system. Traffic 8: 212–225. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 7. Kuhle V, Abrahams GL, Hensel M (2006) Intracellular Salmonella enterica redirect exocytic transport processes in a Salmonella pathogenicity island 2-dependent manner. Traffic 7: 716–730. [DOI] [PubMed] [Google Scholar]
- 8. Garcia-del Portillo F, Zwick MB, Leung KY, Finlay BB (1993) Salmonella induces the formation of filamentous structures containing lysosomal membrane glycoproteins in epithelial cells. Proc Natl Acad Sci U S A 90: 10544–10548. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 9. Rajashekar R, Liebl D, Seitz A, Hensel M (2008) Dynamic remodeling of the endosomal system during formation of Salmonella-induced filaments by intracellular Salmonella enterica . Traffic 9: 2100–2116. [DOI] [PubMed] [Google Scholar]
- 10. Drecktrah D, Levine-Wilkinson S, Dam T, Winfree S, Knodler LA, et al. (2008) Dynamic behavior of Salmonella-induced membrane tubules in epithelial cells. Traffic 9: 2117–2129. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 11. Mota LJ, Ramsden AE, Liu M, Castle JD, Holden DW (2009) SCAMP3 is a component of the Salmonella-induced tubular network and reveals an interaction between bacterial effectors and post-Golgi trafficking. Cell Microbiol 11: 1236–1253. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 12. Schroeder N, Henry T, de Chastellier C, Zhao W, Guilhon AA, et al. (2010) The virulence protein SopD2 regulates membrane dynamics of Salmonella-containing vacuoles. PLoS Pathog 6: e1001002. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 13. Brumell JH, Goosney DL, Finlay BB (2002) SifA, a type III secreted effector of Salmonella typhimurium, directs Salmonella-induced filament (Sif) formation along microtubules. Traffic 3: 407–415. [DOI] [PubMed] [Google Scholar]
- 14. Kuhle V, Jäckel D, Hensel M (2004) Effector proteins encoded by Salmonella pathogenicity island 2 interfere with the microtubule cytoskeleton after translocation into host cells. Traffic 5: 356–370. [DOI] [PubMed] [Google Scholar]
- 15. Beuzon CR, Meresse S, Unsworth KE, Ruiz-Albert J, Garvis S, et al. (2000) Salmonella maintains the integrity of its intracellular vacuole through the action of SifA. EMBO J 19: 3235–3249. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 16. Huotari J, Helenius A (2011) Endosome maturation. EMBO J 30: 3481–3500. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 17. Asch BB, Medina D, Brinkley BR (1979) Microtubules and actin-containing filaments of normal, preneoplastic, and neoplastic mouse mammary epithelial cells. Cancer Res 39: 893–907. [PubMed] [Google Scholar]
- 18. Ellisman MH, Deerinck TJ, Shu X, Sosinsky GE (2012) Picking faces out of a crowd: genetic labels for identification of proteins in correlated light and electron microscopy imaging. Methods Cell Biol 111: 139–155. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 19. Zhang Y, Hensel M (2013) Evaluation of nanoparticles as endocytic tracers in cellular microbiology. Nanoscale 5: 9296–9309. [DOI] [PubMed] [Google Scholar]
- 20. Sandell JH, Masland RH (1988) Photoconversion of some fluorescent markers to a diaminobenzidine product. J Histochem Cytochem 36: 555–559. [DOI] [PubMed] [Google Scholar]
- 21. Rajashekar R, Liebl D, Chikkaballi D, Hensel M (2014) Analyses of Salmonella enterica SPI2 effector protein functions in remodelling the host cell endosomal system. submitted [DOI] [PMC free article] [PubMed] [Google Scholar]
- 22. Knapp PE, Swanson JA (1990) Plasticity of the tubular lysosomal compartment in macrophages. J Cell Sci 95: 433–439. [DOI] [PubMed] [Google Scholar]
- 23. Rubinsztein DC, Shpilka T, Elazar Z (2012) Mechanisms of autophagosome biogenesis. Curr Biol 22: R29–34. [DOI] [PubMed] [Google Scholar]
- 24. Cemma M, Brumell JH (2012) Interactions of pathogenic bacteria with autophagy systems. Curr Biol 22: R540–545. [DOI] [PubMed] [Google Scholar]
- 25. Birmingham CL, Brumell JH (2006) Autophagy recognizes intracellular Salmonella enterica serovar Typhimurium in damaged vacuoles. Autophagy 2: 156–158. [DOI] [PubMed] [Google Scholar]
- 26. Wild P, Farhan H, McEwan DG, Wagner S, Rogov VV, et al. (2011) Phosphorylation of the autophagy receptor optineurin restricts Salmonella growth. Science 333: 228–233. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 27. Fujita N, Morita E, Itoh T, Tanaka A, Nakaoka M, et al. (2013) Recruitment of the autophagic machinery to endosomes during infection is mediated by ubiquitin. J Cell Biol 203: 115–128. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 28. Kabeya Y, Mizushima N, Ueno T, Yamamoto A, Kirisako T, et al. (2000) LC3, a mammalian homologue of yeast Apg8p, is localized in autophagosome membranes after processing. EMBO J 19: 5720–5728. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 29. Tanida I, Waguri S (2010) Measurement of autophagy in cells and tissues. Methods Mol Biol 648: 193–214. [DOI] [PubMed] [Google Scholar]
- 30. Birmingham CL, Smith AC, Bakowski MA, Yoshimori T, Brumell JH (2006) Autophagy controls Salmonella infection in response to damage to the Salmonella-containing vacuole. J Biol Chem 281: 11374–11383. [DOI] [PubMed] [Google Scholar]
- 31. Shpilka T, Weidberg H, Pietrokovski S, Elazar Z (2011) Atg8: an autophagy-related ubiquitin-like protein family. Genome Biol 12: 226. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 32. Mizushima N, Yamamoto A, Hatano M, Kobayashi Y, Kabeya Y, et al. (2001) Dissection of autophagosome formation using Apg5-deficient mouse embryonic stem cells. J Cell Biol 152: 657–668. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 33. Hamacher-Brady A, Brady NR, Logue SE, Sayen MR, Jinno M, et al. (2007) Response to myocardial ischemia/reperfusion injury involves Bnip3 and autophagy. Cell Death Differ 14: 146–157. [DOI] [PubMed] [Google Scholar]
- 34. Steinman RM, Brodie SE, Cohn ZA (1976) Membrane flow during pinocytosis. A stereologic analysis. J Cell Biol 68: 665–687. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 35. Kuhle V, Hensel M (2002) SseF and SseG are translocated effectors of the type III secretion system of Salmonella pathogenicity island 2 that modulate aggregation of endosomal compartments. Cell Microbiol 4: 813–824. [DOI] [PubMed] [Google Scholar]
- 36. Müller P, Chikkaballi D, Hensel M (2012) Functional dissection of SseF, a membrane-integral effector protein of intracellular Salmonella enterica . PLoS ONE 7: e35004. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 37. Boucrot E, Beuzon CR, Holden DW, Gorvel JP, Meresse S (2003) Salmonella typhimurium SifA effector protein requires its membrane-anchoring C-terminal hexapeptide for its biological function. J Biol Chem 278: 14196–14202. [DOI] [PubMed] [Google Scholar]
- 38. Knoops K, Kikkert M, Worm SH, Zevenhoven-Dobbe JC, van der Meer Y, et al. (2008) SARS-coronavirus replication is supported by a reticulovesicular network of modified endoplasmic reticulum. PLoS Biol 6: e226. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 39. Reggiori F, Monastyrska I, Verheije MH, Cali T, Ulasli M, et al. (2010) Coronaviruses Hijack the LC3-I-positive EDEMosomes, ER-derived vesicles exporting short-lived ERAD regulators, for replication. Cell Host Microbe 7: 500–508. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 40. Romero-Brey I, Merz A, Chiramel A, Lee JY, Chlanda P, et al. (2012) Three-dimensional architecture and biogenesis of membrane structures associated with hepatitis C virus replication. PLoS Pathog 8: e1003056. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 41. McGourty K, Thurston TL, Matthews SA, Pinaud L, Mota LJ, et al. (2012) Salmonella inhibits retrograde trafficking of mannose-6-phosphate receptors and lysosome function. Science 338: 963–967. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 42. Pols MS, van Meel E, Oorschot V, ten Brink C, Fukuda M, et al. (2013) hVps41 and VAMP7 function in direct TGN to late endosome transport of lysosomal membrane proteins. Nat Commun 4: 1361. [DOI] [PubMed] [Google Scholar]
- 43. Boucrot E, Henry T, Borg JP, Gorvel JP, Meresse S (2005) The intracellular fate of Salmonella depends on the recruitment of kinesin. Science 308: 1174–1178. [DOI] [PubMed] [Google Scholar]
- 44. Ohlson MB, Huang Z, Alto NM, Blanc MP, Dixon JE, et al. (2008) Structure and function of Salmonella SifA indicate that its interactions with SKIP, SseJ, and RhoA family GTPases induce endosomal tubulation. Cell Host Microbe 4: 434–446. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 45. Wang X, Li D, Qu D, Zhou D (2010) Involvement of TIP60 acetyltransferase in intracellular Salmonella replication. BMC Microbiol 10: 228. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 46. Auweter SD, Bhavsar AP, de Hoog CL, Li Y, Chan YA, et al. (2011) Quantitative mass spectrometry catalogues Salmonella pathogenicity island-2 effectors and identifies their cognate host binding partners. J Biol Chem 286: 24023–24035. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 47. Abrahams GL, Müller P, Hensel M (2006) Functional dissection of SseF, a type III effector protein involved in positioning the Salmonella-containing vacuole. Traffic 7: 950–965. [DOI] [PubMed] [Google Scholar]
- 48. Deiwick J, Salcedo SP, Boucrot E, Gilliland SM, Henry T, et al. (2006) The translocated Salmonella effector proteins SseF and SseG interact and are required to establish an intracellular replication niche. Infect Immun 74: 6965–6972. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 49. Ramsden AE, Holden DW, Mota LJ (2007) Membrane dynamics and spatial distribution of Salmonella-containing vacuoles. Trends Microbiol 15: 516–524. [DOI] [PubMed] [Google Scholar]
- 50. Shea JE, Hensel M, Gleeson C, Holden DW (1996) Identification of a virulence locus encoding a second type III secretion system in Salmonella typhimurium . Proc Natl Acad Sci U S A 93: 2593–2597. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 51. Valdivia RH, Falkow S (1996) Bacterial genetics by flow cytometry: rapid isolation of Salmonella typhimurium acid-inducible promoters by differential fluorescence induction. Mol Microbiol 22: 367–378. [DOI] [PubMed] [Google Scholar]
- 52. Lorkowski M, Felipe-Lopez A, Danzer CA, Hansmeier N, Hensel M (2014) Salmonella enterica invasion of polarized epithelial cells is a highly cooperative effort. Infect Immun 82: 2657–2667. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 53. Kremer JR, Mastronarde DN, McIntosh JR (1996) Computer visualization of three-dimensional image data using IMOD. J Struct Biol 116: 71–76. [DOI] [PubMed] [Google Scholar]
- 54. Hensel M, Shea JE, Waterman SR, Mundy R, Nikolaus T, et al. (1998) Genes encoding putative effector proteins of the type III secretion system of Salmonella Pathogenicity Island 2 are required for bacterial virulence and proliferation in macrophages. Mol Microbiol 30: 163–174. [DOI] [PubMed] [Google Scholar]
- 55. Fung C, Lock R, Gao S, Salas E, Debnath J (2008) Induction of autophagy during extracellular matrix detachment promotes cell survival. Mol Biol Cell 19: 797–806. [DOI] [PMC free article] [PubMed] [Google Scholar]
Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.